Initial Characterization of Stellar Photometry of Roman Images from the OpenUniverse Simulations

NASA’s Nancy Grace Roman Space Telescope (Roman) will provide an opportunity to study dark energy with unprecedented precision and accuracy using several techniques, including measurements of high- Type Ia Supernovae (SNe Ia; ≲ 3.0) via the High-Latitude Time Domain Survey (HLTDS). In this work, we do an initial “benchmark” characterization of the photometric repeatability of stellar fluxes, which must be below 1% when sky noise is subdominant in order to enable a number of calibration requirements. Achieving this level of flux precision requires attention to Roman’s highly structured, spatially varying, undersampled point-spread function (PSF). In this work, we build a library of effective PSFs (ePSFs) compatible with the OpenUniverse HLTDS simulations. Using our library of ePSFs, we recover stellar flux to between 0.6% and 1.2% photometric precision, finding that redder bands perform better by this metric. We also find that flux recovery is improved by up to 20% when a chip (sensor chip assembly, SCA) is divided into eight sub-SCAs in order to account for the spatial variation of the PSF. With our optimized algorithm, we measure nonlinearity due to photometry (magnitude dependence) of ∣ ∣ < 1.93 × 10 dex , which is still larger than stated requirements for detector effects and indicates that further work is necessary. We also measure the dependence of photometric residuals on stellar color and find the largest possible dependence in R062, implying a color-dependent PSF model may be needed. Finally, we characterize the detection efficiency function of each OpenUniverse Roman filter, which will inform future studies.

Duke Scholars

Author Daniel M. Scolnic Physics

Author Arun Kannawadi Jayaraman Physics

Author Michael A. Troxel Physics